Reynolds stress modeling of supercritical narrow channel flows using OpenFOAM: Secondary currents and turbulent flow characteristics

Kadia, Subhojit; Rüther, Nils; Albayrak, Ismail; Pummer, Elena

doi:10.1063/5.0124076

Cited by 16 publications

(6 citation statements)

References 66 publications

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“…A similar trend was reported in the experiments of Demiral, Boes & Albayrak (2020) and the Reynolds-averaged Navier–Stokes (RANS) simulations of Kadia et al. (2022), who showed that secondary motions in open ducts have a topology similarity to those in closed ducts, although both studies featured flow in ducts with free surface in the supercritical regime, which is rather different from our flow case with a flat top surface. Additionally, RANS simulations should be taken with caution, as the prediction of secondary flows is not always accurate.…”

Section: Mean Flow Structuresupporting

confidence: 90%

“…The secondary shear stress is nearly negligible on the bottom and sidewalls, although it has a comparable intensity with the other components at the bottom and top corners, suggesting that its mixing action is limited to the corner regions, whereas it is not relevant close to the side and bottom walls. Similar distributions of the Reynolds stresses τ 11 , τ 22 and τ 12 have also been observed in the studies of Demiral et al (2020) and Kadia et al (2022). This general organization is found regardless of the duct aspect ratio, although characterizing differences are visible, which are due to the imprint of the secondary flows.…”

Section: Frictionsupporting

confidence: 79%

“…(2020) and Kadia et al. (2022). This general organization is found regardless of the duct aspect ratio, although characterizing differences are visible, which are due to the imprint of the secondary flows.…”

Section: Mean Flow Structurementioning

confidence: 96%

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Direct numerical simulation of flow in open rectangular ducts

Yu,

Modesti,

Pirozzoli

2023

J. Fluid Mech.

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We study turbulent flow in open channels with a free surface and rectangular cross-section, for various Reynolds numbers and duct aspect ratios. Direct numerical simulations are used to obtain accurate characterization of the secondary motions, which are found to be more intense than in closed ducts, and to scale with the bulk, rather than with the friction velocity. A notable feature of open-duct flows is the presence of a velocity dip, namely the peak velocity is achieved at some depth underneath the free surface. We find that the depth of the velocity peak increases with the Reynolds number, and correspondingly the flow becomes more symmetric with respect to the horizontal midplane. This is also confirmed from the change of the topology of the secondary motions, which exhibit a strong corner circulation at the free-surface/wall corners at low Reynolds number, which, however, weakens at higher $Re$ . The structure of the mean velocity field is such that the log law applies with good approximation in the direction normal to the nearest wall, which allows us to explain why predictive friction formulae based on the hydraulic diameter concept are successful. Additional analysis shows that the secondary motions account for a large fraction of the frictional drag (up to $15$ %).

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Section: Mean Flow Structuresupporting

confidence: 90%

Section: Frictionsupporting

confidence: 79%

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Direct numerical simulation of flow in open rectangular ducts

Yu,

Modesti,

Pirozzoli

2023

J. Fluid Mech.

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“…To achieve these goals, three tests were performed both experimentally and numerically for discharges Q = 0.045 m 3 /s, 0.07 m 3 /s, and 0.095 m 3 /s; approach flow depths h 0 = 0.109 m, 0.151 m, and 0.175 m; aspect ratios a r = 1.83, 1.32, and 1.14; and Froude numbers Fr ≈ 2. These tested a r and Fr values are comparable to that observed in existing SBTs 17 .…”

Section: Introductionsupporting

confidence: 85%

Experimental and numerical investigations of the water surface profile and wave extrema of supercritical flows in a narrow channel bend

Kadia,

Larsson,

Billstein

et al. 2024

Sci Rep

Self Cite

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Supercritical flows in channel bends, e.g., in steep streams, chute spillways, and flood and sediment bypass tunnels (SBTs), experience cross-waves, which undulate the free surface. The designs of these hydraulic structures and flood protection retaining structures in streams necessitate computing the locations and water depths of the wave extrema. This study numerically and experimentally investigates the water surface profiles along the sidewalls, the wave extrema flow depths, and their angular locations in a narrow channel bend model of the Solis SBT in Switzerland. The 0.2 m wide and 16.75 m long channel has a bend of 6.59 m radius and 46.5° angle of deviation. The tested flow conditions produced Froude numbers ≈ 2 and aspect ratios ranging from 1.14 to 1.83. Two-phase flow simulations were performed in OpenFOAM using the RNG k–ε turbulence closure model and the volume-of-fluid method. The simulated angular locations of the first wave extrema and the corresponding flow depths deviate marginally, within ± 6.3% and ± 2.1%, respectively, from the experimental observations, which signifies good predictions using the numerical model. Larger deviations, especially for the angular locations of the wave extrema, are observed for the existing analytical and empirical approaches. Therefore, the presented numerical approach is a suitable tool in designing the height of the hydraulic structures with bends and conveying supercritical flows. In the future, the model’s application shall be extended to the design of the height and location of retaining walls, embankments, and levees in steep natural streams with bends.

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“…The k-x shear stress transport (SST) is one of the main turbulence models that we are aware of. 6,9 The cost and difficulty of this method are lower than DES (detached eddy simulation) and LES (large eddy simulation) according to Refs. 10 and 11.…”

Section: Introductionmentioning

confidence: 99%

Improved efficiency with concave cavities on S3 surface of a rim-driven thruster

Li,

Yao,

Wang

et al. 2023

Physics of Fluids

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Rim-driven thrusters (RDT) are of great interest for the development of integrated electric motors for underwater vehicles. Gap flow is one of the most prominent flow characteristics and plays an important role in the hydrodynamic performance of RDT. In this study, the rim in a carefully designed RDT was modified with several concave cavities defined by four parameters, and their influence on hydrodynamics was carefully calculated and analyzed. The simulations were performed using the k-ω shear stress transport turbulence model by solving the unsteady Reynolds-averaged Navier–Stokes equations. The numerical method was verified using a popular combination. The numerical results showed that the concave cavities on the rim improve the propulsive efficiency of RDT by a maximum of 3.52%. The increase in the propulsive efficiency is directly associated with the parameters of the concave cavities. Nevertheless, the flow in the gap has a negligible effect on the main flow field through the RDT. According to the numerical analysis, the different pressure integrals at the front and back surfaces of the concave cavities are the main reason for the improvement of the propulsive efficiency. The modification of the rim is helpful and practical for the hydrodynamic optimization of the RDT.

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Reynolds stress modeling of supercritical narrow channel flows using OpenFOAM: Secondary currents and turbulent flow characteristics

Cited by 16 publications

References 66 publications

Direct numerical simulation of flow in open rectangular ducts

Direct numerical simulation of flow in open rectangular ducts

Experimental and numerical investigations of the water surface profile and wave extrema of supercritical flows in a narrow channel bend

Improved efficiency with concave cavities on S3 surface of a rim-driven thruster

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